Wedge wire for use with a narrowed bifurcation vessel

ABSTRACT

A wedge wire for maintaining the patency of an opening to a branch vessel while installing a stent in a main branch of a narrowed bifurcated vessel is provided. The wedge wire has a wedge portion that is larger than the rest of the body of the wedge wire and this wedge portion is used to maintain patency of the branch vessel when a balloon catheter is used to expand a stent in the main branch across the opening of the second branch.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a divisional application of U.S. patent applicationSer. No. 13/770,182, filed Feb. 19, 2013, the entire contents of whichare incorporated herein by reference.

FIELD

The present invention relates to a guide wire system for placing a stentat a vessel bifurcation.

BACKGROUND

Coronary arteries can become narrowed over time, such as when a build upof cholesterol and cellular debris causes a plaque to form. Thesenarrowed vessels are commonly treated with the use of a stent to rexpandthe vessel lumen. These stents are typically metal, meshlike and tubularin shape and can be expanded from a collapsed position on a balloon toan expanded position in the vessel when deployed. Typically, the stentis inserted through a vessel in its collapsed position until the stentreaches the location where the narrowing of the vessel occurs. Once atthe desired location, the stent can be expanded by expanding the balloonto force open the vessel, allowing blood to continue to flow through thevessel. The stent acts as scaffolding to overcome the elastic recoil ofthe vessel wall and becomes incorporated into the vessel wall when a newlining grows over it. Typically, the stent is moved to the site inquestion, crimped on a balloon catheter. The balloon catheter is theninflated to expand the stent.

This method is used when the narrowing occurs along the main vessel orbranch of the main vessel. However, when the narrowing occurs where onevessel branches away from another (a bifurcation), this presentsadditional challenges and requires additional techniques to be used todeal with the narrowing. One of these techniques is what is commonlyreferred to as the “kissing balloon” technique. It involves placing astent in the main vessel so it runs across the opening to the branchvessel. Once the stent is in place, two guide wires can be placed (onein the main vessel, one partly down the main vessel, then down thebranch vessel) with each guide wire having a balloon catheter runningalong each guide wire. Where the branch vessel opens into the mainvessel, the balloons can be inflated, with one of the balloons used tofurther expand the stent, while the other balloon is used to balloonthrough the sidewall of the stent and into the branch vessel,maintaining its patency. However, this kissing balloon technique has itsdrawbacks. It typically results in damage to the vessel branching offthe main vessel due to the expansion of the balloon against the branchvessel. This will increase the risk of renarrowing the side branchvessel in the weeks to months after the procedure.

SUMMARY OF THE INVENTION

In an aspect, a wedge wire, having a wedge that is larger than the bodyof the wedge wire is provided. The wedge of the wedge wire can be usedto maintain patency of the branch vessel when the balloon placed on thefirst guide wire sitting in the main branch of the vessel is inflatedwithin the stent and used to enlarge the stent.

In another aspect, a wedge wire for maintaining the patency of anopening to a branch vessel while installing a stent in a main branch ofa narrowed bifurcated vessel is provided. The wedge wire comprises: aproximate end and a distal end; a wedge portion positioned proximate thedistal end; a first portion extending between the proximate end and thewedge portion; and a distal portion extending between the distal end andthe wedge portion. The wedge portion has a thickness that is greaterthan the thickness of the first portion and the thickness of the seconddistal portion.

In another aspect, a method of treating a narrowing of a bifurcatedvessel, the bifurcated vessel having a main vessel, a branch vessel andan opening formed between the branch vessel and the main vessel isprovided. The method comprises: deploying a stent in the main vesselacross the opening to the branch vessel; using a first guide wire,positioning an uninflated balloon in the stent; providing a wedge wirehaving a proximate end and a distal end and a wedge portion proximatethe distal end, the wedge portion having a thickness greater than therest of the wedge wire; maneuvering the distal end of the wedge wirethrough a sidewall of the stent and through the opening into the branchvessel until the wedge portion of the wedge wire is positioned in theopening; and inflating the balloon to enlarge the stent while using thewedge portion of the wedge wire to maintain pendency in the opening.

DESCRIPTION OF THE DRAWINGS

A preferred embodiment of the present invention is described below withreference to the accompanying drawings, in which:

FIG. 1 is a schematic illustration of a narrowed vessel bifurcation;

FIG. 2 is a schematic illustration of a prior art method where a stentis used in a first step of opening the narrowed vessel bifurcation;

FIG. 3 is a schematic illustration of a “kissing balloon” technique asis used in the prior art;

FIG. 4 illustrates a side view of a wedge wire;

FIG. 5 illustrates an end view of the wedge wire of FIG. 4;

FIG. 6 illustrates a first step of a method for inserting a stent in avessel bifurcation; and

FIG. 7 illustrates a second step of the method first shown in FIG. 6.

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

FIG. 1 illustrates a vessel bifurcation 10 where a narrowing of thesurrounding vessels has occurred, such as by the buildup of plaque,lesions, etc. Typically, the vessel bifurcation 10 can include a mainvessel 20 with a branch vessel 30 having an opening 32 into the mainvessel 20 and extending at an angle away from the main vessel 20. Themain vessel 20 and the branch vessel 30 is a branch off of the mainbranch of the coronary artery.

The vessel bifurcation 10 also has a number of narrowings 40 locatedaround the opening 32 of the branch vessel 30, formed by plaque,lesions, etc. that constrict flow through the main vessel 20. Thesenarrowings 40 define a passage running through the narrowings 40 that isnarrower than the main vessel 20.

FIG. 2 illustrates the first steps of a prior art method of opening thenarrowed vessel bifurcation 10. A stent 50 can be inserted into the mainvessel 20 so that it extends across the opening 32 of the branch vessel30. Typically, a first guide wire 60 is used to position the stent 50and balloon catheter (not shown) in place. The first guide wire 60 canbe passed through the main branch 20 passing between the narrowings 40and used to insert the stent 50 which would cross the opening 32 of thebranch vessel 30. Typically, the walls of the branch vessel 30 becomepinched close to the opening 32 of the branch vessel 30.

FIG. 3 illustrates a “kissing balloon technique” as is commonly used inthe prior art. After the stent 50 is inserted in the bifurcation vessel100, a second guide wire 70 can be passed through the main vessel 20,through the side wall of the stent 50 at the opening 32 of the branchvessel 30 and into the branch vessel 30. A first balloon 65 can beadvanced provided on the first guide wire 60 and positioned in the mainbranch so that it is placed within the stent 50 and an uninflated secondballoon 75 can be positioned on the second guide wire 70 and guided sothat it partially extends through the side wall of the stent 50 into theopening 30 of the branch vessel 30.

The second balloon 75 can be inflated simultaneously with the firstballoon 65 on the first guide wire 60 being used to expand the stent 50.This maneuver will maintain patency of the main vessel 20, and thebranch vessel 30.

However, this kissing balloon technique typically causes damage to thebranch vessel 30 because the inflation of the first balloon 65 and thesecond balloon 75 can pinch the branch vessel 30 near the opening 32 ofthe branch vessel 30. In some cases, this damage could cause a nidus forneointimal hyperplasia (scarring) which may cause renarrowing of thebranch vessel 30.

FIG. 5 illustrates a wedge wire 100 for use with a narrowed bifurcatedvessel. Unlike conventional guide wires that have a relatively uniformdiameter, the wedge wire 100 varies in thickness along a portion of itslength. The wedge wire 100 can have a proximate end 102, used to feedthe wedge wire 100 through a vessel, and a distal end 104, that isinserted into the vessel the wedge wire 100 is being fed through. Thewedge wire 100 can also have a wedge portion 105 provided close to thedistal end 104 of the wedge wire 100.

The wedge wire 100 can have a first portion 106 that has a firstthickness and/or diameter. The wedge portion 105 can have a secondthickness and/or diameter that is larger than the first thickness and/ordiameter of the first portion 106 of the wedge wire 100. A distalportion 108 can be provided between the distal end 104 of the wedge wire100 and the wedge portion 105 of the wedge wire 100. The distal portion108 can have a thickness and/or diameter that is smaller than thethickness and/or diameter of the wedge portion 105 of the wedge wire100, which would be similar in diameter to the proximal portion of thefirst portion 106. As shown in FIG. 7, the wedge portion 105 isconfigured to connect the first portion 106 and the distal portion 108.

Although diameter is used to describe the cross-section of the wedgewire 100, a person skilled in the art would understand that the wedgewire 100 could have a cross-section that is not circular, such aselliptical, etc.

In various aspects, the wedge portion 105 of the wedge wire 100 couldhave various diameters of 0.5 mm, 1 mm, 1.5 mm, 2 mm, etc. In oneaspect, the length of the distal portion 108 can be approximately 10 mm,making the wedge portion 105 of the wedge wire 100 approximately 10mmfrom the distal end 104 of the wedge wire 100. The wedge portion 105 maybe tapered at its ends so as to not catch on the meshwork of the stentas it passed through the stent sidewall.

The wedge wire 100 can be used in conjunction with a stent to deal witha narrowing of a bifurcated vessel. FIG. 6 illustrates a first step ofanother method where a stent 150 is first deployed across the opening132 of branch vessel 130 extending from a main vessel 120. Narrowings140 are present in the main vessel 120. A first guide wire/ballooncatheder 160 can be used to position the stent 150 in place.

FIG. 7 illustrates a second step of the method. The stent has now beendeployed. The main branch guide wire 160 now has an uniflated balloonpositioned on it (this in most cases is a new balloon and the initialballoon that had deployed the stent has been removed and replaced). Thefirst guide wire 160 can be used to position the uniflated balloon 165inside the stent 150. The distal end 104 of the wedge wire 100 can thenbe maneuvered up the main vessel 120 to the opening 32 of the branchvessel 130. At the opening 32, the distal end 104 of the wedge wire 100can be inserted through a side wall of the stent 150 and through theopening 132 of the branch vessel 130 and into the branch vessel 130. Thedistal end 104 of the wedge wire 100 can be extended into the branchvessel 130 until the wedge portion 105 of the wedge wire 100 ispositioned in the opening 32 of the branch vessel 130.

The wedge portion 105 of the wedge wire 100 can be used to maintainpatency of the branch vessel 130 when the balloon 165 placed on thefirst guide wire 160 is inflated within the stent 150 and used toenlarge the stent 150. In this manner a second balloon catheter is notneeded because the wedge portion 105 of the wedge wire 100 maintainspatency of the opening 132.

Additionally, the wedge portion 105 of the wedge wire 100 could also beused to enlarge the opening in the sidewall of the stent 150, if needed.

The foregoing is considered as illustrative only of the principles ofthe invention. Further, since numerous changes and modifications willreadily occur to those skilled in the art, it is not desired to limitthe invention to the exact construction and operation shown anddescribed, and accordingly, all such suitable changes or modificationsin structure or operation which may be resorted to are intended to fallwithin the scope of the claimed invention.

1. A wedge wire for maintaining the patency of an opening to a branchvessel while installing a stent in a main branch of a narrowedbifurcated vessel, the wedge wire comprising: a proximate end and adistal end; a wedge portion positioned proximate the distal end; a firstportion extending between the proximate end and the wedge portion; and adistal portion extending between the distal end and the wedge portion,wherein the wedge portion is located between the first portion of thewedge wire and the distal portion of the wedge wire and is configured toconnect the first portion and the distal portion, and wherein the wedgeportion has a thickness that is greater than a thickness of the firstportion and a thickness of the distal portion.
 2. The wedge wire ofclaim 1, wherein the thickness of the first portion and the thickness ofthe distal portion are substantially the same.
 3. The wedge wire ofclaim 1, wherein the first portion, the wedge portion and the distalportion have circular cross-sections.
 4. The wedge wire of claim 1,wherein a diameter of the wedge portion is from 1.0 mm to 2 mm and adiameter of the first portion is less than 0.5 mm.
 5. The wedge wire ofclaim 1, wherein the wedge portion has tapered ends.
 6. The wedge wireof claim 1, wherein the distal portion has a length of 10 mm. 7-14.(canceled)